CAVALCANTI, A. G.; http://lattes.cnpq.br/6554424252007231; CAVALCANTI, Arthur Gonçalves.
Abstract:
The general relativity theory predicts black hole type solutions, which are characterized
by the existence of an event horizon. As an example, the metric obtained by Ba~nados-
Teitelboim-Zanelli (BTZ), which is a soluton of the gravitation in (2 + 1)-dimensions in
what is considered a negative cosmological constant. In recent years, noncommutative
black holes have been investigated by many authors in the literature. In particular, the
BTZ metric non-commutative was obtained considering the equivalent, which exists in three dimensions, between gravitation and Chern-Simons theory, which is a quantum theory topological elds in three dimensions, and using it mapping Seiberg-Witter with the solution of (2 + 1)-dimensions. The presence of divergences in quantum eld theory leads to consider the possibility of modifying the principle of Heisenberg uncertainty by introducing a fundamental length scale, and this modi cation generate corrections to the thermodynamic properties of black holes. One of the e ects associated with the black hole type solutions, regardless of the space-time dimension is the thermal emission (Hawking radiation), which is seen as a process of tunneling due to vacuum uctuations that happens in the region near the event horizon . In this work, in order to investigate the corrections due to noncommutativity and the principle of widespread uncertainty, we consider the metric BTZ noncommutative. For this, we use tunneling formalism via Hamilton-Jacobi method.